The present invention relates to radio communication systems and communication control methods.
In these years, heterogeneous networks (HetNets) have been proposed, in which a plurality of types of radio base stations having different transmission powers (transmission capabilities), such as a macro base station, a pico base station, a femto base station, and a remote radio head, are installed in a multi-layered manner. In heterogeneous networks, a base station having a high transmission power (for example, a macro base station) tends to be selected as the radio connection destination of a user equipment in a cell searching stage or a handover stage compared with a base station having a low transmission power (for example, a pico base station). Therefore, connections from user equipments tend to concentrate on a base station having a high transmission power, causing excessive communication load.
To solve the above problem, Patent Document 1, for example, discloses a technology that controls a communication cell boundary in a variable manner by changing an offset value (correction value) that numerically reduces the power level received by a mobile station, according to parameters, such as the load and the amount of traffic on a radio communication system. The mobile station in Patent Document 1 selects a destination base station (macro-cell base station, micro-cell base station) according to the offset power level (reception power).
In the configuration of Patent Document 1 in which a correction value that numerically reduces the power level received by a mobile station is changed according to parameters, such as the load and the amount of traffic on a radio communication system, however, since the effects imposed by noise power and interference from another radio base station (in other words, imposed by components other than desired waves) on the desired waves are not appropriately taken into account in the selection of the radio connection destination, the radio connection destination of a user equipment may be selected inappropriately.
Taking this situation into account, an object of the present invention is to correct a characteristic value (reception power or the like) used to select the radio connection destination with the effects of components other than the desired waves on the desired waves taken into account, to more appropriately select the radio connection destination of a user equipment (mobile station) in a radio communication system having a plurality of types of radio base stations having different transmission powers (transmission capabilities).
A radio communication system according to the present invention includes a first radio base station that forms a first cell; a plurality of second radio base stations each of which forms, in the first cell, a second cell having a smaller area than the first cell; and a plurality of mobile stations each of which includes a radio communication section capable of executing radio communication by sending and receiving radio waves to and from each of the first radio base station and a second radio base station respectively corresponding to cells in which the mobile station is located among the first cell and the second cells. Each of the plurality of mobile stations further includes a characteristic-value measuring section that measures a first reception characteristic value and a second reception characteristic value related to radio waves sent from each of the first radio base station and the second radio base station corresponding to the first cell and the second cell in which the mobile station is located; and a characteristic-value reporting section that reports the first reception characteristic value and the second reception characteristic value corresponding to each of the first radio base station and the second radio base station to the first radio base station through the radio communication section. The first radio base station includes a destination determination section that determines, for each of the plurality of mobile stations, a radio base station having the best first reception characteristic value among the first radio base station corresponding to the first reception characteristic value and the second reception characteristic value reported from the mobile station and the second radio base station corresponding to the first reception characteristic value and the second reception characteristic value reported from the mobile station, as a radio base station to which the mobile station should connect; a mobile-station classification section that classifies mobile stations in which the second reception characteristic value corresponding to the first radio base station is better than the second reception characteristic value corresponding to the second radio base station into a first mobile-station group, and classifies mobile stations in which the second reception characteristic value corresponding to the second radio base station is better than the second reception characteristic value corresponding to the first radio base station into a second mobile-station group, among the plurality of mobile stations; a correction-value specifying section that specifies, according to a distribution of differences between the first reception characteristic values corresponding to the first radio base station and the first reception characteristic values corresponding to the second radio base station, measured by the mobile stations included in the second mobile-station group, a correction value used to correct the first reception characteristic value corresponding to each of the second radio base stations, measured by each of the plurality of mobile stations, so as to reduce the number of mobile stations having the first reception characteristic values with which the destination determination section determines that the mobile stations should connect to the first radio base station, among the mobile stations included in the second mobile-station group; and a correction-value reporting section that reports the correction value specified by the correction-value specifying section to the plurality of mobile stations. Each of the plurality of mobile stations further includes a characteristic-value correcting section that corrects the first reception characteristic value related to radio waves sent from the second radio base station, measured by the characteristic-value measuring section, by using the correction value reported from the correction-value reporting section of the first radio base station. Either the first radio base station or each of the plurality of mobile stations includes a destination selecting section that selects, as a radio base station to which the mobile station should connect, a radio base station corresponding to the best first reception characteristic value among the first reception characteristic value corresponding to the first radio base station and the first reception characteristic value corrected with the correction value, corresponding to the second radio base station.
The first reception characteristic value is calculated from radio waves that the mobile station tries to receive (desired radio waves) and can be, for example, reception power (reference signal received power) or reception quality (reference signal received quality). The second reception characteristic value is calculated from the desired radio waves and components other than the desired radio waves (for example, noise power or interference power for the desired radio waves) and can be, for example, the signal to interference-plus-noise ratio, the signal to interference ratio, or the signal to noise ratio.
In the above-described configuration, the first reception characteristic values of the second radio base stations, used to select the radio base stations to which the mobile stations should connect, are corrected with the correction value specified according to the distribution of the differences between the first reception characteristic values corresponding to the first radio base station and the first reception characteristic values corresponding to the second radio base stations, measured by the mobile stations included in the second mobile-station group classified according to the second reception characteristic values. Therefore, a radio base station having a better second reception characteristic value tends to be selected as the connection destination of each mobile station.
It is preferable that the correction-value specifying section of the first radio base station specify the correction value used to correct the first reception characteristic value corresponding to each of the second radio base stations, measured by each of the plurality of mobile stations, such that the number of mobile stations having the first reception characteristic values with which the destination determination section determines that the mobile stations should connect to the first radio base station becomes the minimum among the mobile stations included in the second mobile-station group.
According to the above-described configuration, among the mobile stations included in the second mobile-station group, in which the second reception characteristic values of the second radio base stations are larger, the number of mobile stations having the first reception characteristic values with which the destination determination section determines that the mobile stations should connect to the first radio base station is reduced.
Another radio communication system according to the present invention includes a first radio base station that forms a first cell; a plurality of second radio base stations each of which forms, in the first cell, a second cell having a smaller area than the first cell; and a plurality of mobile stations each of which includes a radio communication section capable of executing radio communication by sending and receiving radio waves to and from each of the first radio base station and a second radio base station respectively corresponding to cells in which the mobile station is located among the first cell and the second cells. Each of the plurality of mobile stations further includes a characteristic-value measuring section that measures a first reception characteristic value and a second reception characteristic value related to radio waves sent from each of the first radio base station and the second radio base station corresponding to the first cell and the second cell in which the mobile station is located; and a characteristic-value reporting section that reports the first reception characteristic value and the second reception characteristic value corresponding to each of the first radio base station and the second radio base station to the first radio base station through the radio communication section. The first radio base station includes a destination determination section that determines, for each of the plurality of mobile stations, a radio base station having the best first reception characteristic value among the first radio base station corresponding to the first reception characteristic value and the second reception characteristic value reported from the mobile station and the second radio base station corresponding to the first reception characteristic value and the second reception characteristic value reported from the mobile station, as a radio base station to which the mobile station should connect; a mobile-station classification section that classifies mobile stations in which the second reception characteristic value corresponding to the first radio base station is better than the second reception characteristic value corresponding to the second radio base station into a first mobile-station group, and classifies mobile stations in which the second reception characteristic value corresponding to the second radio base station is better than the second reception characteristic value corresponding to the first radio base station into a second mobile-station group, among the plurality of mobile stations; a correction-value specifying section that specifies, according to a distribution of differences between the first reception characteristic values corresponding to the first radio base station and the first reception characteristic values corresponding to the second radio base station, measured by the mobile stations included in the first mobile-station group, a correction value used to correct the first reception characteristic value corresponding to each of the second radio base stations, measured by each of the plurality of mobile stations, so as to reduce the number of mobile stations having the first reception characteristic values with which the destination determination section determines that the mobile stations should connect to the second radio base station, among the mobile stations included in the first mobile-station group; and a correction-value reporting section that reports the correction value specified by the correction-value specifying section to the plurality of mobile stations. Each of the plurality of mobile stations further includes a characteristic-value correcting section that corrects the first reception characteristic value related to radio waves sent from the second radio base station, measured by the characteristic-value measuring section, by using the correction value reported from the correction-value reporting section of the first radio base station. Either the first radio base station or each of the plurality of mobile stations includes a destination selecting section that selects, as a radio base station to which the mobile station should connect, a radio base station corresponding to the best first reception characteristic value among the first reception characteristic value corresponding to the first radio base station and the first reception characteristic value corrected with the correction value, corresponding to the second radio base station.
In the above-described configuration, the first reception characteristic values of the second radio base stations, used to select the radio base stations to which the mobile stations should connect, are corrected with the correction value specified according to the distribution of the differences between the first reception characteristic values corresponding to the first radio base station and the first reception characteristic values corresponding to the second radio base stations, measured by the mobile stations included in the first mobile-station group classified according to the second reception characteristic values. Therefore, a radio base station having a better second reception characteristic value tends to be selected as the connection destination of each mobile station.
It is preferable that the correction-value specifying section of the first radio base station specify the correction value used to correct the first reception characteristic value corresponding to each of the second radio base stations, measured by each of the plurality of mobile stations, such that the number of mobile stations having the first reception characteristic values with which the destination determination section determines that the mobile stations should connect to the second radio base station becomes the minimum among the mobile stations included in the first mobile-station group.
According to the above-described configuration, the number of mobile stations having first reception characteristic values with which the destination determination section determines that the mobile stations should connect to the second radio base stations is reduced, among the mobile stations included in the first mobile-station group, in which the second reception characteristic values of the first radio base station are larger.
Another radio communication system according to the present invention includes a first radio base station that forms a first cell; a plurality of second radio base stations each of which forms, in the first cell, a second cell having a smaller area than the first cell; and a plurality of mobile stations each of which includes a radio communication section capable of executing radio communication by sending and receiving radio waves to and from each of the first radio base station and a second radio base station respectively corresponding to cells in which the mobile station is located among the first cell and the second cells. Each of the plurality of mobile stations further includes a characteristic-value measuring section that measures a first reception characteristic value and a second reception characteristic value related to radio waves sent from each of the first radio base station and the second radio base station corresponding to the first cell and the second cell in which the mobile station is located; and a characteristic-value reporting section that reports the first reception characteristic value and the second reception characteristic value corresponding to each of the first radio base station and the second radio base station to the first radio base station through the radio communication section. The first radio base station includes a destination determination section that determines, for each of the plurality of mobile stations, a radio base station having the best first reception characteristic value among the first radio base station corresponding to the first reception characteristic value and the second reception characteristic value reported from the mobile station and the second radio base station corresponding to the first reception characteristic value and the second reception characteristic value reported from the mobile station, as a radio base station to which the mobile station should connect; a mobile-station classification section that classifies mobile stations in which the second reception characteristic value corresponding to the first radio base station is better than the second reception characteristic value corresponding to the second radio base station into a first mobile-station group, and classifies mobile stations in which the second reception characteristic value corresponding to the second radio base station is better than the second reception characteristic value corresponding to the first radio base station into a second mobile-station group, among the plurality of mobile stations; a correction-value specifying section that specifies, according to a distribution of differences between the first reception characteristic values corresponding to the first radio base station and the first reception characteristic values corresponding to the second radio base station, measured by the mobile stations included in the second mobile-station group, and a distribution of differences between the first reception characteristic values corresponding to the first radio base station and the first reception characteristic values corresponding to the second radio base station, measured by the mobile stations included in the first mobile-station group, a correction value used to correct the first reception characteristic value corresponding to each of the second radio base stations, measured by each of the plurality of mobile stations, so as to reduce the sum of the number of mobile stations having the first reception characteristic values with which the destination determination section determines that the mobile stations should connect to the first radio base station, among the mobile stations included in the second mobile-station group, and the number of mobile stations having the first reception characteristic values with which the destination determination section determines that the mobile stations should connect to the second radio base station, among the mobile stations included in the first mobile-station group; and a correction-value reporting section that reports the correction value specified by the correction-value specifying section to the plurality of mobile stations. Each of the plurality of mobile stations further includes a characteristic-value correcting section that corrects the first reception characteristic value related to radio waves sent from the second radio base station, measured by the characteristic-value measuring section, by using the correction value reported from the correction-value reporting section of the first radio base station. Either the first radio base station or each of the plurality of mobile stations includes a destination selecting section that selects, as a radio base station to which the mobile station should connect, a radio base station corresponding to the best first reception characteristic value among the first reception characteristic value corresponding to the first radio base station and the first reception characteristic value corrected with the correction value, corresponding to the second radio base station.
In the above-described configuration, the first reception characteristic values of the second radio base stations, used to select the radio base stations to which the mobile stations should connect, are corrected with the correction value specified according to the distribution of the differences between the first reception characteristic values corresponding to the first radio base station and the first reception characteristic values corresponding to the second radio base stations, measured by the mobile stations included in the second mobile-station group classified according to the second reception characteristic values and according to the distribution of the differences between the first reception characteristic values corresponding to the first radio base station and the first reception characteristic values corresponding to the second radio base stations, measured by the mobile stations included in the first mobile-station group classified according to the second reception characteristic values. Therefore, a radio base station having a better second reception characteristic value tends to be selected as the connection destination of each mobile station.
It is preferable that the correction-value specifying section of the first radio base station specify the correction value used to correct the first reception characteristic value corresponding to each of the second radio base stations, measured by each of the plurality of mobile stations, such that the sum of the number of mobile stations having the first reception characteristic values with which the destination determination section determines that the mobile stations should connect to the first radio base station, among the mobile stations included in the second mobile-station group, and the number of mobile stations having the first reception characteristic values with which the destination determination section determines that the mobile stations should connect to the second radio base station, among the mobile stations included in the first mobile-station group, becomes the minimum.
According to the above-described configuration, the sum of the number of mobile stations having the first reception characteristic values with which the destination determination section determines that the mobile stations should connect to the first radio base station among the mobile stations included in the second mobile-station group, in which the second reception characteristic values of the second radio base stations are larger, and the number of mobile stations having the first reception characteristic values with which the destination determination section determines that the mobile stations should connect to the second radio base stations among the mobile stations included in the first mobile-station group, in which the second reception characteristic values of the first radio base station are larger, is reduced.
It is further preferable that, at first predetermined intervals, each of the plurality of mobile stations measure and report the first reception characteristic value and the second reception characteristic value, and the first radio base station determine the radio base station to which each of the plurality of mobile stations should connect, classify the plurality of mobile stations, specify the correction value, and report the correction value to the plurality of mobile stations; and, at second predetermined intervals shorter than the first predetermined intervals, each of the plurality of mobile stations measure the first reception characteristic value and correct the first reception characteristic value related to radio waves sent from the second radio base station by using the correction value, and either the first radio base station or each of the plurality of mobile stations select the radio base station to which the mobile station should connect.
In the above-described configuration, while the frequency at which the mobile stations measure the second reception characteristic values is reduced, the first reception characteristic values related to radio waves sent from the second radio base stations are corrected based on the correction value specified according to the second reception characteristic values. Therefore, the radio connection destinations can be selected according to the second reception characteristic values, and the power consumption of the mobile stations can be reduced at the same time.
A radio base station according to the present invention is a first radio base station in a radio communication system comprising: the first radio base station that forms a first cell; a plurality of second radio base stations each of which forms, in the first cell, a second cell having a smaller area than the first cell; and a plurality of mobile stations each of which includes a radio communication section capable of executing radio communication by sending and receiving radio waves to and from each of the first radio base station and a second radio base station respectively corresponding to cells in which the mobile station is located among the first cell and the second cells, a characteristic-value measuring section that measures a first reception characteristic value and a second reception characteristic value related to radio waves sent from each of the first radio base station and the second radio base station corresponding to the first cell and the second cell in which the mobile station is located, and a characteristic-value reporting section that reports the first reception characteristic value and the second reception characteristic value corresponding to each of the first radio base station and the second radio base station to the first radio base station through the radio communication section. The first radio base station includes: a destination determination section that determines, for each of the plurality of mobile stations, a radio base station having the best first reception characteristic value among the first radio base station corresponding to the first reception characteristic value and the second reception characteristic value reported from the mobile station and the second radio base station corresponding to the first reception characteristic value and the second reception characteristic value reported from the mobile station, as a radio base station to which the mobile station should connect; a mobile-station classification section that classifies mobile stations in which the second reception characteristic value corresponding to the first radio base station is better than the second reception characteristic value corresponding to the second radio base station into a first mobile-station group, and classifies mobile stations in which the second reception characteristic value corresponding to the second radio base station is better than the second reception characteristic value corresponding to the first radio base station into a second mobile-station group, among the plurality of mobile stations; a correction-value specifying section that specifies, according to a distribution of differences between the first reception characteristic values corresponding to the first radio base station and the first reception characteristic values corresponding to the second radio base station, measured by the mobile stations included in the second mobile-station group, a correction value used to correct the first reception characteristic value corresponding to each of the second radio base stations, measured by each of the plurality of mobile stations, so as to reduce the number of mobile stations having the first reception characteristic values with which the destination determination section determines that the mobile stations should connect to the first radio base station, among the mobile stations included in the second mobile-station group; and a correction-value reporting section that reports the correction value specified by the correction-value specifying section to the plurality of mobile stations.
Another radio base station according to the present invention is a first radio base station in a radio communication system comprising: the first radio base station that forms a first cell; a plurality of second radio base stations each of which forms, in the first cell, a second cell having a smaller area than the first cell; and a plurality of mobile stations each of which includes a radio communication section capable of executing radio communication by sending and receiving radio waves to and from each of the first radio base station and a second radio base station respectively corresponding to cells in which the mobile station is located among the first cell and the second cells, a characteristic-value measuring section that measures a first reception characteristic value and a second reception characteristic value related to radio waves sent from each of the first radio base station and the second radio base station corresponding to the first cell and the second cell in which the mobile station is located, and a characteristic-value reporting section that reports the first reception characteristic value and the second reception characteristic value corresponding to each of the first radio base station and the second radio base station to the first radio base station through the radio communication section. The first radio base station includes: a destination determination section that determines, for each of the plurality of mobile stations, a radio base station having the best first reception characteristic value among the first radio base station corresponding to the first reception characteristic value and the second reception characteristic value reported from the mobile station and the second radio base station corresponding to the first reception characteristic value and the second reception characteristic value reported from the mobile station, as a radio base station to which the mobile station should connect; a mobile-station classification section that classifies mobile stations in which the second reception characteristic value corresponding to the first radio base station is better than the second reception characteristic value corresponding to the second radio base station into a first mobile-station group, and classifies mobile stations in which the second reception characteristic value corresponding to the second radio base station is better than the second reception characteristic value corresponding to the first radio base station into a second mobile-station group, among the plurality of mobile stations; a correction-value specifying section that specifies, according to a distribution of differences between the first reception characteristic values corresponding to the first radio base station and the first reception characteristic values corresponding to the second radio base station, measured by the mobile stations included in the first mobile-station group, a correction value used to correct the first reception characteristic value corresponding to each of the second radio base stations, measured by each of the plurality of mobile stations, so as to reduce the number of mobile stations having the first reception characteristic values with which the destination determination section determines that the mobile stations should connect to the second radio base station, among the mobile stations included in the first mobile-station group; and a correction-value reporting section that reports the correction value specified by the correction-value specifying section to the plurality of mobile stations.
Another radio base station according to the present invention is a first radio base station in a radio communication system comprising: the first radio base station that forms a first cell; a plurality of second radio base stations each of which forms, in the first cell, a second cell having a smaller area than the first cell; and a plurality of mobile stations each of which includes a radio communication section capable of executing radio communication by sending and receiving radio waves to and from each of the first radio base station and a second radio base station respectively corresponding to cells in which the mobile station is located among the first cell and the second cells, a characteristic-value measuring section that measures a first reception characteristic value and a second reception characteristic value related to radio waves sent from each of the first radio base station and the second radio base station corresponding to the first cell and the second cell in which the mobile station is located, and a characteristic-value reporting section that reports the first reception characteristic value and the second reception characteristic value corresponding to each of the first radio base station and the second radio base station to the first radio base station through the radio communication section. The first radio base station includes: a destination determination section that determines, for each of the plurality of mobile stations, a radio base station having the best first reception characteristic value among the first radio base station corresponding to the first reception characteristic value and the second reception characteristic value reported from the mobile station and the second radio base station corresponding to the first reception characteristic value and the second reception characteristic value reported from the mobile station, as a radio base station to which the mobile station should connect; a mobile-station classification section that classifies mobile stations in which the second reception characteristic value corresponding to the first radio base station is better than the second reception characteristic value corresponding to the second radio base station into a first mobile-station group, and classifies mobile stations in which the second reception characteristic value corresponding to the second radio base station is better than the second reception characteristic value corresponding to the first radio base station into a second mobile-station group, among the plurality of mobile stations; a correction-value specifying section that specifies, according to a distribution of differences between the first reception characteristic values corresponding to the first radio base station and the first reception characteristic values corresponding to the second radio base station, measured by the mobile stations included in the second mobile-station group, and a distribution of differences between the first reception characteristic values corresponding to the first radio base station and the first reception characteristic values corresponding to the second radio base station, measured by the mobile stations included in the first mobile-station group, a correction value used to correct the first reception characteristic value corresponding to each of the second radio base stations, measured by each of the plurality of mobile stations, so as to reduce the sum of the number of mobile stations having the first reception characteristic values with which the destination determination section determines that the mobile stations should connect to the first radio base station, among the mobile stations included in the second mobile-station group, and the number of mobile stations having the first reception characteristic values with which the destination determination section determines that the mobile stations should connect to the second radio base station, among the mobile stations included in the first mobile-station group; and a correction-value reporting section that reports the correction value specified by the correction-value specifying section to the plurality of mobile stations.
A communication control method according to the present invention is for a radio communication system that includes a first radio base station that forms a first cell; a plurality of second radio base stations each of which forms, in the first cell, a second cell having a smaller area than the first cell; and a plurality of mobile stations each of which includes a radio communication section capable of executing radio communication by sending and receiving radio waves to and from each of the first radio base station and a second radio base station respectively corresponding to cells in which the mobile station is located among the first cell and the second cells. The communication control method includes: measuring a first reception characteristic value and a second reception characteristic value related to radio waves sent from each of the first radio base station and the second radio base station corresponding to the first cell and the second cell in which the mobile station is located and reporting the first reception characteristic value and the second reception characteristic value corresponding to each of the first radio base station and the second radio base station to the first radio base station through the radio communication section, in each of the plurality of mobile stations; determining, for each of the plurality of mobile stations, a radio base station having the best first reception characteristic value among the first radio base station corresponding to the first reception characteristic value and the second reception characteristic value reported from the mobile station and the second radio base station corresponding to the first reception characteristic value and the second reception characteristic value reported from the mobile station, as a radio base station to which the mobile station should connect; classifying mobile stations in which the second reception characteristic value corresponding to the first radio base station is better than the second reception characteristic value corresponding to the second radio base station into a first mobile-station group, and classifying mobile stations in which the second reception characteristic value corresponding to the second radio base station is better than the second reception characteristic value corresponding to the first radio base station into a second mobile-station group, among the plurality of mobile stations; specifying, according to a distribution of differences between the first reception characteristic values corresponding to the first radio base station and the first reception characteristic values corresponding to the second radio base station, measured by the mobile stations included in the second mobile-station group, a correction value used to correct the first reception characteristic value corresponding to each of the second radio base stations, measured by each of the plurality of mobile stations, so as to reduce the number of mobile stations having the first reception characteristic values with which it is determined that the mobile stations should connect to the first radio base station, among the mobile stations included in the second mobile-station group; reporting the specified correction value to the plurality of mobile stations; correcting the measured first reception characteristic value related to radio waves sent from the second radio base station by using the correction value reported from the first radio base station, in each of the plurality of mobile stations; and selecting, as a radio base station to which the mobile station should connect, a radio base station corresponding to the best first reception characteristic value among the first reception characteristic value corresponding to the first radio base station and the first reception characteristic value corrected with the correction value, corresponding to the second radio base station.
Another communication control method according to the present invention is for a radio communication system that includes a first radio base station that forms a first cell; a plurality of second radio base stations each of which forms, in the first cell, a second cell having a smaller area than the first cell; and a plurality of mobile stations each of which includes a radio communication section capable of executing radio communication by sending and receiving radio waves to and from each of the first radio base station and a second radio base station respectively corresponding to cells in which the mobile station is located among the first cell and the second cells. The communication control method includes: measuring a first reception characteristic value and a second reception characteristic value related to radio waves sent from each of the first radio base station and the second radio base station corresponding to the first cell and the second cell in which the mobile station is located and reporting the first reception characteristic value and the second reception characteristic value corresponding to each of the first radio base station and the second radio base station to the first radio base station through the radio communication section, in each of the plurality of mobile stations; determining, for each of the plurality of mobile stations, a radio base station having the best first reception characteristic value among the first radio base station corresponding to the first reception characteristic value and the second reception characteristic value reported from the mobile station and the second radio base station corresponding to the first reception characteristic value and the second reception characteristic value reported from the mobile station, as a radio base station to which the mobile station should connect; classifying mobile stations in which the second reception characteristic value corresponding to the first radio base station is better than the second reception characteristic value corresponding to the second radio base station into a first mobile-station group, and classifying mobile stations in which the second reception characteristic value corresponding to the second radio base station is better than the second reception characteristic value corresponding to the first radio base station into a second mobile-station group, among the plurality of mobile stations; specifying, according to a distribution of differences between the first reception characteristic values corresponding to the first radio base station and the first reception characteristic values corresponding to the second radio base station, measured by the mobile stations included in the first mobile-station group, a correction value used to correct the first reception characteristic value corresponding to each of the second radio base stations, measured by each of the plurality of mobile stations, so as to reduce the number of mobile stations having the first reception characteristic values with which it is determined that the mobile stations should connect to the second radio base station, among the mobile stations included in the first mobile-station group; reporting the specified correction value to the plurality of mobile stations; correcting the measured first reception characteristic value related to radio waves sent from the second radio base station by using the correction value reported from the first radio base station, in each of the plurality of mobile stations; and selecting, as a radio base station to which the mobile station should connect, a radio base station corresponding to the best first reception characteristic value among the first reception characteristic value corresponding to the first radio base station and the first reception characteristic value corrected with the correction value, corresponding to the second radio base station.
Another communication control method according to the present invention is for a radio communication system that includes a first radio base station that forms a first cell; a plurality of second radio base stations each of which forms, in the first cell, a second cell having a smaller area than the first cell; and a plurality of mobile stations each of which includes a radio communication section capable of executing radio communication by sending and receiving radio waves to and from each of the first radio base station and a second radio base station respectively corresponding to cells in which the mobile station is located among the first cell and the second cells. The communication control method includes: measuring a first reception characteristic value and a second reception characteristic value related to radio waves sent from each of the first radio base station and the second radio base station corresponding to the first cell and the second cell in which the mobile station is located and reporting the first reception characteristic value and the second reception characteristic value corresponding to each of the first radio base station and the second radio base station to the first radio base station through the radio communication section, in each of the plurality of mobile stations; determining, for each of the plurality of mobile stations, a radio base station having the best first reception characteristic value among the first radio base station corresponding to the first reception characteristic value and the second reception characteristic value reported from the mobile station and the second radio base station corresponding to the first reception characteristic value and the second reception characteristic value reported from the mobile station, as a radio base station to which the mobile station should connect; classifying mobile stations in which the second reception characteristic value corresponding to the first radio base station is better than the second reception characteristic value corresponding to the second radio base station into a first mobile-station group, and classifying mobile stations in which the second reception characteristic value corresponding to the second radio base station is better than the second reception characteristic value corresponding to the first radio base station into a second mobile-station group, among the plurality of mobile stations; specifying, according to a distribution of differences between the first reception characteristic values corresponding to the first radio base station and the first reception characteristic values corresponding to the second radio base station, measured by the mobile stations included in the second mobile-station group, and a distribution of differences between the first reception characteristic values corresponding to the first radio base station and the first reception characteristic values corresponding to the second radio base station, measured by the mobile stations included in the first mobile-station group, a correction value used to correct the first reception characteristic value corresponding to each of the second radio base stations, measured by each of the plurality of mobile stations, so as to reduce the sum of the number of mobile stations having the first reception characteristic values with which it is determined that the mobile stations should connect to the first radio base station, among the mobile stations included in the second mobile-station group, and the number of mobile stations having the first reception characteristic values with which it is determined that the mobile stations should connect to the second radio base station, among the mobile stations included in the first mobile-station group; reporting the specified correction value to the plurality of mobile stations; correcting the measured first reception characteristic value related to radio waves sent from the second radio base station by using the correction value reported from the first radio base station, in each of the plurality of mobile stations; and selecting, as a radio base station to which the mobile station should connect, a radio base station corresponding to the best first reception characteristic value among the first reception characteristic value corresponding to the first radio base station and the first reception characteristic value corrected with the correction value, corresponding to the second radio base station.
Communication elements (such as the macro base station 100, the pico base stations 200, and the user equipments UE) in the radio communication system 1 perform radio communication according to a predetermined radio access technology, such as long term evolution (LTE). In the present embodiment, an example case will be described in which the radio communication system 1 operates according to LTE, but there is no intention to limit the technical scope of the present invention. The present invention can also be applied to other radio access technologies after necessary design changes are made.
The macro base station 100 and the pico base stations 200 are connected to each other by wire or by radio. The macro base station 100 forms a macro cell Cm. In the macro cell Cm, N (N is a natural number) user equipments UE (UE1, UE2, . . . , UEN) are located. In
The pico base stations 200 form pico cells Cp. The pico cells Cp are formed in the macro cell Cm formed by the macro base station 100 to which the pico base stations 200 that form the pico cells Cp are connected. In one macro cell Cm, a plurality of pico cells Cp can be formed.
Each of the base stations (the macro base station 100 and the pico base stations 200) can communicate by radio with a user equipment UE located in the cell of that base station. Conversely, a user equipment UE can communicate by radio with the base station (macro base station 100 or pico base station 200) corresponding to the cell C (macro cell Cm or pico cell Cp) in which that user equipment UE is located. The user equipment UE can select the radio-connection-destination base station according to the reception power (reference signal received power, RSRP) of a radio signal sent from each base station. For example, the user equipment UE can select a base station that sends a radio signal corresponding to the highest reception power RSRP as the radio-connection-destination base station.
Since the macro base station 100 has a higher radio transmission capability (maximum transmission power, average transmission power, etc.) than the pico base stations 200, the macro base station 100 can communicate by radio with a user equipment UE located farther away. Therefore, the macro cell Cm is larger in area than the pico cells Cp. For example, the macro cell Cm has a radius of about several hundred meters to several tens of kilometers, whereas the pico cells Cp have a radius of about several meters to several tens of meters.
As understood from the foregoing description, the macro base station 100 and the pico base stations 200 in the radio communication system 1 form a heterogeneous network (HetNet), in which a plurality of types of radio base stations having different transmission powers (transmission capabilities) are installed in a multi-layer manner (see 3rd Generation Partnership Project; Technical Specification Group Radio Access Network; Evolved Universal Terrestrial Radio Access (E-UTRA); Further advancements for E-UTRA physical layer aspects (Release 9); 3GPP IR 36.814 V9.0.0 (2010-03); Section 9A, Heterogeneous Deployments).
Since the pico cells Cp are formed inside (are overlaid on) the macro cell Cm in a multi-layer manner, when a user equipment UE is located in a pico cell Cp, it can be understood that the user equipment UE can receive radio waves (radio signals) from both the pico base station 200 forming that pico cell Cp and the macro base station 100 forming the macro cell Cm that includes the pico cell Cp.
Any radio communication method can be used between each base station and a user equipment UE. For example, orthogonal frequency division multiple access (OFDMA) may be employed for downlink, and single-carrier frequency division multiple access (SC-FDMA) may be employed for uplink.
The radio communication section 310 executes radio communication with a base station (macro base station 100, pico base station 200). The radio communication section 310 includes transmission and reception antennas 312, a receiving circuit for receiving radio waves from a base station and converting them to an electrical signal, and a transmission circuit for converting an electrical signal, such as a voice signal, to radio waves and sending them. The radio communication section 310 also receives a correction value A and destination information I from the macro base station 100 forming the macro cell Cm in which the user equipment UEn is located, and sends, to the macro base station 100, the reception power RSRPM and the signal to interference-plus-noise ratio SINRM of radio waves received from the macro base station 100 and the reception power RSRPP and the signal to interference-plus-noise ratio SINRP of radio waves received from the pico base station (details will be described later).
The storage 350 stores the correction value A received from the macro base station 100 and other information and may be a random access memory (RAM), for example.
For the sake of simplicity, in the following description, the reception power RSRPM and the signal to interference-plus-noise ratio SINRM of radio waves received from the macro base station 100 are called macro reception power RSRPM and a macro signal to interference-plus-noise ratio SINRM, respectively, in some cases; and the reception power RSRPP and the signal to interference-plus-noise ratio SINRP of radio waves received from the pico base station are called pico reception power RSRPP and a pico signal to interference-plus-noise ratio SINRP, respectively, in some cases. In addition, only the symbols (that is, RSRPM, SINRM, RSRPP, and SINRP) are used to indicate the corresponding reception powers and the signal to interference-plus-noise ratios in some cases.
The controller 330 includes a characteristic-value measuring section 332, a characteristic-value-for-analysis reporting section 334, a characteristic-value correcting section 336, a characteristic-value-for-connection reporting section 338, and a connection section 340. The controller 330, together with the characteristic-value measuring section 332, the characteristic-value-for-analysis reporting section 334, the characteristic-value correcting section 336, the characteristic-value-for-connection reporting section 338, and the connection section 340 included in the controller 330, can be functional blocks implemented when a central processing unit (CPU), not shown, included in the user equipment UE executes a computer program stored in the storage 350 and functions according to the computer program. The detailed operation of the controller 330 will be described later.
The radio communication section 110 connects by radio to a user equipment UE to execute radio communication. The radio communication section 110 includes transmission and reception antennas 112, a receiving circuit for receiving radio waves from the user equipment UE and converting them to an electrical signal, and a transmission circuit for converting an electrical signal, such as a voice signal, to radio waves and sending them. The radio communication section 110 also sends the correction value A and the destination information I to the user equipment UE located in the macro cell Cm formed by the macro base station 100 and receives, from the user equipment UE located in the macro cell Cm formed by the macro base station 100, the reception power RSRPM and the signal to interference-plus-noise ratio SINRM of radio waves received from the macro base station 100 and the reception power RSRPP and the signal to interference-plus-noise ratio SINRP of radio waves received from the pico base station (details will be described later).
The base-station communication section 120 executes communication with another base station (macro base station 100, pico base station 200) and sends and receives electrical signals to and from the other base station. When the macro base station 100 communicates with another base station by radio, it is understood as a matter of course that the radio communication section 110 can also operate as the base-station communication section 120.
The controller 130 includes a destination-for-analysis determination section 132, a user-equipment classification section 134, a correction-value specifying section 136, a correction-value reporting section 138, and a destination selecting section 140. The controller 130, together with the destination-for-analysis determination section 132, the user-equipment classification section 134, the correction-value specifying section 136, the correction-value reporting section 138, and the destination selecting section 140 included in the controller 130, can be functional blocks implemented when a CPU, not shown, included in the macro base station 100 executes a computer program stored in a storage, not shown, and functions according to the computer program. The detailed operation of the controller 130 will be described later.
The radio communication section 210 executes radio communication with a user equipment UE. The radio communication section 210 includes transmission and reception antennas 212, a receiving circuit for receiving radio waves from the user equipment UE and converting them to an electrical signal, and a transmission circuit for converting an electrical signal, such as a voice signal, to radio waves and sending them.
The base-station communication section 220 executes communication with the macro base station 100 to which the pico base station 200 is connected and sends and receives electrical signals to and from the macro base station 100. When the pico base station 200 communicates with the macro base station 100 by radio, the radio communication section 210 may also operate as the base-station communication section 220.
The pico base station 200 can receive information (for example, the correction value A, the destination information I, or other information) sent from the macro base station 100 and forward the information to the user equipment UE, and can receive information (RSRPMn, SINRMn, RSRPPn, and SINRPn, or other information) sent from the user equipment UE and forward the information to the macro base station 100. More specifically, the controller 230 supplies, to the radio communication section 210, an electrical signal that the base-station communication section 220 of the pico base station 200 receives from the base-station communication section 120 of the macro base station 100. The radio communication section 210 converts the supplied electrical signal to radio waves and sends them to the user equipment UE. The controller 230 also supplies, to the base-station communication section 220, an electrical signal received and converted by the radio communication section 210 of the pico base station 200. The base-station communication section 220 sends the supplied electrical signal to the macro base station 100. With the above-described configuration, even if it is difficult for the user equipment UE to communicate with the macro base station 100 by radio because the user equipment UE is close to the pico base station 200, necessary information can be exchanged between the user equipment UE and the macro base station 100.
The controller 230 of the pico base station 200 can be a functional block implemented when a CPU, not shown, included in the pico base station 200 executes a computer program stored in a storage, not shown, and functions according to the computer program.
An outline of how the radio connection destination is selected according to the reception power RSRP will be described with reference to
For the sake of explanation, it is assumed in the following description that the macro base station 100 is disposed at a position L0, the pico base station 200 is disposed at a position L3, and the macro reception power RSRPM is equal to the pico reception power RSRPP at a position L2. It is also assumed that the user equipment UE is disposed at a position Lu closer to the macro base station 100 than the position L2 is.
As shown in
However, the technology in which the user equipment UE simply connects by radio to a base station that transmits radio waves having a high reception power has the following problems.
A plurality of user equipments UE are classified into a set SM and a set SP according to the signal to interference-plus-noise ratio SINR. The set SM is a set of user equipments UE in which the macro signal to interference-plus-noise ratio SINRM exceeds the pico signal to interference-plus-noise ratio SINRP. The set SP is a set of user equipments UE in which the pico signal to interference-plus-noise ratio SINRP exceeds the macro signal to interference-plus-noise ratio SINRM.
In general, as shown in the figure, the difference Δ in reception power RSRP at the user equipments UE belonging to the set SM tends to exceed the difference Δ in reception power RSRP at the user equipments UE belonging to the set SP. In other words, a correlation is generally recognized between the reception power RSRP and the signal to interference-plus-noise ratio SINR at the user equipments UE. However, for each of the user equipments UE, it is not necessarily true that the larger the reception power RSRP, the larger the signal to interference-plus-noise ratio SINR. This matter will be described below specifically with reference to
When the differences Δ are positive (Δ>0), the macro reception power RSRPMn exceeds the pico reception power RSRPPn. Therefore, it is determined according to the simple reception power RSRP criterion that the user equipments UEn included in the set RM should connect to the macro base station 100. On the other hand, when the differences Δ are negative (Δ<0), the pico reception power RSRPPn exceeds the macro reception power RSRPMn. Therefore, it is determined according to the simple reception power RSRP criterion that the user equipments UEn included in the set RP should connect to the pico base station 200.
As shown in
On the other hand, the user equipments UE included in the set SP are divided into a subset FP included in the set RP and a subset DM included in the set RM. In other words, as a result of the connection-destination selection based on the reception power RSRP, it is determined that some user equipments UE included in the set SP (user equipments UE included in the subset FP) should connect to the pico base station 200, for which the signal to interference-plus-noise ratios SINR are higher, but that the other user equipments UE included in the set SP (user equipments UE included in the subset DM) should connect to the macro base station 100, for which the signal to interference-plus-noise ratios SINR are lower.
When the signal to interference-plus-noise ratio SINR of radio waves is low, the reception quality of the user equipment UE is low even if the reception power RSRP is high. Therefore, in some cases, it is not appropriate, in terms of the convenience of the users of the user equipments UE and the communication quality in the entire radio communication system 1, that a large number of user equipments UE are connected to a base station for which the signal to interference-plus-noise ratios SINR of radio waves are lower.
On the other hands, the user equipments UE have a high processing load when measuring the signal to interference-plus-noise ratios SINR of radio waves (in particular, measuring interference power necessary for SINR measurement). Therefore, in some cases, it is undesirable, in terms of reducing power consumption and improving processing speed in the user equipments, that the user equipments UE always measure the signal to interference-plus-noise ratios SINR of radio waves and select the radio connection destinations.
In view of these situations, the present embodiment corrects the reception power RSRP used to select the radio connection destination of each user equipment UE, with a correction value A specified by considering the signal to interference-plus-noise ratio SINR, so that a base station for which the signal to interference-plus-noise ratio SINR is higher is selected as the radio connection destination of the user equipment UE.
How the correction value A is specified and the destination base station is selected for a user equipment UE in the first embodiment will be described with reference to
The characteristic-value measuring section 332 of each user equipment UEn measures the reception power RSRPMn and the signal to interference-plus-noise ratio SINRMn of radio waves received from the macro base station 100 forming the macro cell Cm in which the user equipment UEn is located, and the reception power RSRPPn and the signal to interference-plus-noise ratio SINRPn of radio waves received from the pico base station 200 forming the pico cell Cp in which the user equipment UEn is located (step S100). The measured macro reception power RSRPMn, macro signal to interference-plus-noise ratio SINRMn, pico reception power RSRPPn, and pico signal to interference-plus-noise ratio SINRPn are supplied to the characteristic-value-for-analysis reporting section 334. The characteristic-value-for-analysis reporting section 334 reports (sends) the supplied macro reception power RSRPMn, macro signal to interference-plus-noise ratio SINRMn, pico reception power RSRPPn, and pico signal to interference-plus-noise ratio SINRPn to the macro base station 100 through the radio communication section 310 (step S110).
The radio communication section 110 of the macro base station 100 receives the reported macro reception power RSRPMn, macro signal to interference-plus-noise ratio SINRMn, pico reception power RSRPPn, and pico signal to interference-plus-noise ratio SINRPn from each user equipment UE and supplies them to the controller 130. Since the macro cell Cm includes N user equipments UE, it is understood that N macro reception powers RSRPMn, macro signal to interference-plus-noise ratios SINRMn, N pico reception powers RSRPPn, and N pico signal to interference-plus-noise ratios SINRPn are supplied to the controller 130.
The destination-for-analysis determination section 132 of the controller 130 determines, as the destination base station of each user equipment UE, a radio base station corresponding to the highest reception power RSRP (that is, a radio base station having the best reception power RSRP) of the macro reception power RSRPMn and the pico reception power RSRPPn supplied from the radio communication section 110 (step S120). More specifically, the destination-for-analysis determination section 132 generates a table TR (
The destination base station determined in step S120 is a virtual destination base station used to specify a correction value A in step S140, and does not necessarily match the actual destination base station selected in a subsequent step S230.
Among a plurality of user equipments UE, the user-equipment classification section 134 of the controller 130 classifies, according to the macro signal to interference-plus-noise ratios SINRM and the pico signal to interference-plus-noise ratios SINRP supplied from the radio communication section 110, user equipments UE in which the macro signal to interference-plus-noise ratio SINRMn is larger (that is, better) than the pico signal to interference-plus-noise ratio SINRPn into the set SM, and user equipments UE in which the pico signal to interference-plus-noise ratio SINRPn is larger than the macro signal to interference-plus-noise ratio SINRMn into the set SP (step S130). More specifically, the user-equipment classification section 134 generates a table TS (
Step S120 and step S130 may be executed sequentially or in parallel.
Next, the correction-value specifying section 136 of the controller 130 specifies a correction value A according to the table TR supplied from the destination-for-analysis determination section 132 and the table TS supplied from the user-equipment classification section 134 so as to reduce the number of user equipments UE included in the product set DM (DM=RM∩SP) of the set RM of the user equipments UE that should connect to the macro base station 100 and the set SP of the user equipments UE in which the pico signal to interference-plus-noise ratio SINRP is higher (step S140). The correction value A may be specified such that the number of user equipments UE included in the set DM becomes the minimum.
The correction value A is specified according to the distribution of the differences Δ between the macro reception powers RSRPM and the pico reception powers RSRPP in the set SP. For example, as shown in
The correction-value reporting section 138 reports (sends) the correction value A specified by the correction-value specifying section 136 through the radio communication section 110 to each of the plurality of user equipments UE (step S150). The correction value A reported from the macro base station 100 is received by the radio communication section 310 of each user equipment UE and is supplied to and stored in the storage 350.
The characteristic-value measuring section 332 of each user equipment UEn measures the macro reception power RSRPMn and the pico reception power RSRPPn corresponding to the resident cells C (Cm and Cp) (step S200).
The measured pico reception power RSRPPn is supplied to the characteristic-value correcting section 336. The characteristic-value correcting section 336 reads the correction value A reported from the macro base station 100 and stored in the storage 350 and uses it to correct the supplied pico reception power RSRPPn to obtain the corrected pico reception power RSRPPn′ (RSRPPn′=RSRPPn+A) (step S210). The corrected pico reception power RSRPPn′ is supplied to the characteristic-value-for-connection reporting section 338. The measured macro reception power RSRPMn is directly supplied to the characteristic-value-for-connection reporting section 338.
In summary, only the pico reception power RSRPPn at the user equipment UEn is offset with the correction value A to provide the corrected pico reception power RSRPPn′.
The characteristic-value-for-connection reporting section 338 reports (sends) the supplied macro reception power RSRPMn and the corrected pico reception power RSRPPn′ to the macro base station through the radio communication section 310 (step S220). The reported macro reception power RSRPMn and the corrected pico reception power RSRPPn′ are supplied to the destination selecting section 140 of the controller 130.
The destination selecting section 140 of the macro base station 100 selects, for each user equipment UEn as the radio base station to which the user equipment UEn should connect, a radio base station corresponding to the highest reception power RSRP (that is, the best reception power RSRP) of the supplied macro reception power RSRPMn and the corrected pico reception power RSRPPn′ (step S230). Then, the destination selecting section 140 reports destination information, In indicating the destination radio base station selected for each user equipment UEn to the user equipment UEn through the radio communication section 310 (step S240).
The destination information In reported from the macro base station 100 is received by the radio communication section 310 of the user equipment UEn and is supplied to the connection section 340 of the controller 330. The connection section 340 executes radio connection according to the supplied destination information In (step S250). Specifically, when the user equipment UEn has already connected by radio to the radio base station indicated by the destination information In, the user equipment UEn maintains the radio connection. On the other hand, when the user equipment UEn has not yet connected by radio to the radio base station indicated by the destination information In, the user equipment UEn executes handover to the indicated radio base station.
As described above, the correction value A is specified for the user equipment UE (steps S100 to S150), and the radio base station to which the user equipment UE should connect is selected (steps S200 to S250). For simplicity of description, the setting of the correction value A and the selection of the radio connection destination have been explained above collectively. The setting of the correction value A and the selection of the radio connection destination can be executed with different frequencies.
For example, the correction value A can be specified (steps S100 to S150) at predetermined first intervals (for example, every one second), and the radio connection destination can be selected (steps S200 to S250) at predetermined second intervals (for example every one millisecond) that are shorter than the first intervals. With the above-described configuration, the measurement of the signal to interference-plus-noise ratio SINR, which imposes a high load on the controller 330 of the user equipment UE, is performed at a lower frequency, and the correction value A is specified with the signal to interference-plus-noise ratio SINR being taken into consideration.
After the correction value A is specified and the radio connection destination is selected according to the correction value A, described above, some of the plurality of user equipments UE connected to the macro base station 100 are handed over to the pico base station 200 (off-loaded to the pico cell Cp). More specifically, as shown in
As understood from the foregoing description, the correction of the pico reception power RSRPP (the increase with the correction value A) in the characteristic-value correcting section 336 of each user equipment UE increases the apparent pico reception power RSRPP at the user equipment UE, thus expanding the area of the pico cell Cp formed by the pico base station 200.
The user equipments UE included in the portion enclosed by a thick frame in
In the embodiment described above, since the pico reception power RSRPP, used to select the radio connection destination of each user equipment UE, is corrected with the correction value A specified with the signal to interference-plus-noise ratio SINR being taken into consideration, a radio base station for which the signal to interference-plus-noise ratio SINR is higher (that is, the reception quality is better) tends be selected as the destination base station of each user equipment UE.
A second embodiment of the present invention will be described below. For units having the same effects or functions in the following example embodiments as in the first embodiment, the reference symbols used in the above description will be used again, and a description thereof will be omitted, if unnecessary.
Unlike the distribution of the differences Δ shown in
On the other hand, the user equipments UE included in the set SM are divided into a subset FM included in the set RM and a subset DP included in the set RP. In other words, as a result of the connection-destination selection based on the reception power RSRP, it is determined that some user equipments UE included in the set SM (user equipments UE included in the subset FM) should connect to the macro base station 100, for which the signal to interference-plus-noise ratios SINR are higher, but that the other user equipments UE included in the set SM (user equipments UE included in the subset DP) should be connected to the pico base station 200, for which the signal to interference-plus-noise ratios SINR are lower.
In the same way as in the first embodiment, it is not appropriate, in terms of the convenience of the users of the user equipments UE and the communication quality in the entire radio communication system 1, that a large number of user equipments UE are connected to a base station for which the signal to interference-plus-noise ratios SINR of radio waves are lower.
Therefore, in the second embodiment, the correction-value specifying section 136 of the controller 130 specifies a correction value A according to the table TR supplied from the destination-for-analysis determination section 132 and the table TS supplied from the user-equipment classification section 134 so as to reduce the number of user equipments UE included in the product set DP (DP=RP∩SM) of the set RP of the user equipments UE that should connect to the pico base station 200 and the set SM of the user equipments in which the macro signal to interference-plus-noise ratio SINRM is higher (step S140). The correction value A may be specified such that the number of user equipments UE included in the set DP becomes the minimum.
The correction value A is specified according to the distribution of the differences Δ between the macro reception powers RSRPM and the pico reception powers RSRPP in the set SM. For example, as shown in
After the correction value A is specified and the radio connection destination is selected according to the correction value A, described above, some of the plurality of user equipments UE connected to the pico base station 200 are handed over to the macro base station 100.
The embodiment described above achieves the same effects and advantages as the first embodiment.
In the first embodiment, the correction value A is specified such that the number of user equipments UE included in the set DM is reduced. In the second embodiment, the correction value A is specified such that the number of user equipments UE included in the set DP is reduced. There is no difference, however, in that the user equipments UE included in either the set DM or the set DP are connected to a radio base station for which the signal to interference-plus-noise ratio is lower. Therefore, in a third embodiment, the correction value A is specified so as to reduce the number of user equipments UE connected to a radio base station for which the signal to interference-plus-noise ratio is lower.
Specifically, the correction-value specifying section 136 of a macro base station 100 in the third embodiment specifies a correction value A according to the table TR supplied from the destination-for-analysis determination section 132 and the table TS supplied from the user-equipment classification section 134 so as to reduce the sum of the number of user equipments UE included in the product set DM (DM=RM ∩SP) of the set RM of the user equipments UE that should connect to the macro base station 100 and the set SP of the user equipments UE in which the pico signal to interference-plus-noise ratio SINRP is higher and the number of user equipments UE included in the product set DP (DP=RP∩SM) of the set RP of the user equipments UE that should connect to the pico base station 200 and the set SM of the user equipments UE in which the macro signal to interference-plus-noise ratio SINRM is higher (in other words, the number of user equipments UE included in the union DS (DS=DM∪DP) of the set DM and the set DP) (step S140). The correction value A may be specified such that the number of user equipments UE included in the set DS becomes the minimum.
The correction value A is specified according to the distribution of the differences Δ between the macro reception powers RSRPM and the pico reception powers RSRPP in the set SP and the distribution of the differences Δ between the macro reception powers RSRPM and the pico reception powers RSRPP in the set SM. For example, as shown in
The embodiment described above achieves the same effects and advantages as the first embodiment and the second embodiment. In view of the fact that, as the correction value A increases, the number of user equipments UE included in the set DM becomes smaller and the number of user equipments UE included in the set DP becomes larger, a more appropriate correction value A can be specified according to the trade-off between the number of user equipments UE included in the set DM and the number of user equipments UE included in the set DP, compared with a configuration in which the correction value A is specified according to only the number of user equipments UE included in the set DM or only the number of user equipments UE included in the set DP. Therefore, it is possible to increase the number of user equipments UE connected to a radio base station for which the signal to interference-plus-noise ratio SINR is higher.
The embodiments described above can be modified in various ways. Specific example modifications will be described below. Two or more of the following modifications selected in a desired manner can be appropriately combined so long as no mutual contradiction occurs.
The above-described embodiments can be combined with any interference control technology. For example, the above-described embodiments can be combined with enhanced inter-cell interference coordination (eICIC) shown in
Each of the embodiments of the present invention can be combined with eICIC, described above. Specifically, in eICIC in which the destination base station of the user equipment UE is selected according to the comparison between the reception power RSRPM of radio waves sent from the macro base station 100 and the reception power RSRPP of radio waves sent from the pico base station 200 when the macro base station 100 stops the transmission of radio waves, the correction value A can be specified in the same way as in the above-described embodiments by using the signal to interference-plus-noise ratio SINRM of radio waves sent from the macro base station 100 and the signal to interference-plus-noise ratio SINRP of radio waves sent from the pico base station 200 when the macro base station 100 stops the transmission of radio waves.
In the above-described combination, interference between radio waves sent from the base stations is reduced by eICIC, and an appropriate correction value is specified (in other words, the radio connection destination of the user equipment UE is appropriately selected) in each of the embodiments of the present invention. Therefore, the radio resources are used more fairly and more efficiently. When eICIC is applied, there is an increased possibility that the reception power RSRP and the signal to interference-plus-noise ratio SINR are uncorrelated (
In the above-described embodiments, a radio-wave reception characteristic used as a direct criterion when the radio base station to which a user equipment UE should connect is selected is the reception power (RSRP). Reception quality (reference signal received quality, RSRQ) or the like may be employed as the radio-wave reception characteristic used as a criterion. In other words, the radio-wave reception characteristic used as a direct criterion when the destination base station is selected (that is, the reception characteristic used in the destination-for-analysis determination section 132 and the destination selecting section 140 of the macro base station 100) needs to be measurable or computable for each base station in the user equipment UE without any high-load processing such as interference-power measurement.
In the above-described embodiments, the correction value A is specified with the signal to interference-plus-noise ratio (SINR) being taken into account to obtain a correction value that takes account of the effect imposed by components other than the desired waves on the desired waves (leading to the selection of the radio connection destination). The signal to interference ratio (SIR) or the signal to noise ratio (SNR), for example, may be taken into consideration when the correction value A is specified. In other words, user equipments UE may be classified according to, for example, the signal to interference ratio (SIR) or the signal to noise ratio (SNR).
In the above-described embodiments, the reception power RSRP is employed, which is a characteristic value that indicates that the larger it is, the better the reception state is. Another characteristic value that indicates a better reception state as it becomes smaller may be employed. For example, the reciprocal of a value indicating the reception power may be used as a characteristic value. In that case, a radio base station corresponding to a smaller characteristic value is determined or selected by the destination-for-analysis determination section 132 and the destination selecting section 140 as the radio connection destination of the user equipment UE.
In the above-described embodiments, the pico base stations 200 are exemplified as base stations having a lower transmission capability than the macro base station 100. A micro base station, a nano base station, a femto base station, a remote radio head, or the like may be used as a base station having a lower transmission capability.
In particular, as an element of the radio communication system 1, a combination of a plurality of base stations having different transmission capabilities (for example, a combination of a macro base station, a pico base station, and a femto base station) may be used. In that case, it is preferable that the correction value A be determined independently according to the transmission capability of each base station (for example, that a correction value A1 determined for the pico base station be different from a correction value A2 determined for the femto base station).
In the above-described embodiments, the destination selecting section 140 of the macro base station 100 selects a radio base station serving as the connection destination of a user equipment UEn according to the reception power RSRP (RSRPMn, RSRPPn′) reported from the characteristic-value-for-connection reporting section 338 of the user equipment UEn. A destination selection section provided in the controller 330 of the user equipment UE may select a radio base station serving as the connection destination according to the reception power RSRP (RSRPMn, RSRPPn′) obtained by the user equipment UE itself.
The user equipments UE are devices capable of communicating with each base station (macro base station 100, pico base station 200) by radio. For example, the user equipments UE may be portable telephone terminals, such as feature phones or smart phones, desktop personal computers, notebook personal computers, ultra-mobile personal computers (UMPCs), portable game machines, or other radio terminals.
The functions executed by the CPU in each element (macro base station 100, pico base station 200, user equipment UE) in the radio communication system 1 may be executed by hardware instead of the CPU, or may be executed by a programmable logic device, such as a field programmable gate array (FPGA) or a digital signal processor (DSP).
Number | Date | Country | Kind |
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2011-177428 | Aug 2011 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2012/068185 | 7/18/2012 | WO | 00 | 9/25/2013 |
Publishing Document | Publishing Date | Country | Kind |
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WO2013/024656 | 2/21/2013 | WO | A |
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